# Circular interpolation in Python

I have two systems, each of which has a direction sensor (0-360 degrees), but the sensors can provide wildly different values depending on the orientation of each system and the linearity of each sensor. I have a mechanical reference that I can use to generate a table of where each system is actually pointing. This yields a table with three columns:

``````Physical  SystemA  SystemB
--------  -------  -------
000.0     005.7    182.3
005.0     009.8    178.4
...       ...      ...
``````

From just the data shown, we can see that SystemA isn't far from the physical reference, but SystemB is about 180 degrees off, and goes in the opposite direction (imagine it is mounted upside-down).

I need to be able to map back and forth between all three values: If SystemA reports something is at 105.7, I need to tell the user what physical direction that is, then tell SystemB to point to the same location. The same if SystemB makes the initial report. And the user can request both systems to point to a desired physical direction, so SystemA and SystemB would need to be told where to point.

Linear interpolation isn't hard, but I'm having trouble when data is going in opposite directions, and is modular/cyclical.

Is there a Pythonic way to do all these mappings?

EDIT: Let's focus on the most difficult case, where we have two paired lists of values:

``````A        B
-----    -----
0.0    182.5
10.0    172.3
20.0    161.4
...      ...
170.0      9.7
180.0    359.1
190.0    348.2
...      ...
340.0    163.6
350.0    171.8
``````

Let's say the lists come from two different radars with pointers that aren't aligned to North or anything else, but we did manually take the above data by moving a target around and seeing where each radar had to point to see it.

When Radar A says "I have a target at 123.4!", where do I need to aim Radar B to see it? If Radar B finds a target, where do I tell Radar A to point?

List A wraps between the last and first elements, but list B wraps nearer to the middle of the list. List A increases monotonically, while list B decreases monotonically. Notice that the size of a degree on A is generally not the same size as a degree on B.

Is there a simple interpolator that will wrap correctly when:

1. Interpolating from List A to list B.

2. Interpolating from List B to list A.

It is OK to use two separate interpolator instantiations, one for going in each direction. I'll assume a linear (first-order) interpolator is OK, but I may want to use higher-order or spline interpolation in the future.

Some test cases:

• A = 356.7, B = ?

• A = 179.2, B = ?

-
Is it possible to calculate what the sensor readings will be with a simple equation, like `systemA = (physical*coef + offset) % 360` or are the values sufficiently non-linear to make that impractical? If it is, you can just use algebra to solve for any unknown value given any known one. If not, then you're probably right about needing interpolation. Modular interpolation isn't usually too bad, you just need to check if the points you're interpolating between are more than `modulus/2` (e.g. 180 degrees) apart, indicating that the shortest path between them wraps around. –  Blckknght Apr 8 '13 at 21:26
Your example doesn't make sense. The readings for B keep decreasing until the last 2, where they increase, plus they're already smaller than the ones at the top of the list. If you fix that I might be able to show some example code with my answer. –  Mark Ransom Apr 11 '13 at 3:25
A general comment for interpolation of angular data that may be of some help. It can be really useful to break the data down into unit components and perform your interpolation on the components individually, and then recombine the resultant interpolants with a sector-safe arctan method (e.g. arctan2(y,x)). –  Thom Chubb May 6 '13 at 6:19

This is what works for me. Could probably use some clean-up.

``````class InterpolatedArray(object):
""" An array-like object that provides interpolated values between set points.
"""
points = None
wrap_value = None
offset = None

def _mod_delta(self, a, b):
""" Perform a difference within a modular domain.
Return a value in the range +/- wrap_value/2.
"""
limit = self.wrap_value / 2.
val = a - b
if val < -limit: val += self.wrap_value
elif val > limit: val -= self.wrap_value
return val

def __init__(self, points, wrap_value=None):
"""Initialization of InterpolatedArray instance.

Parameter 'points' is a list of two-element tuples, each of which maps
an input value to an output value.  The list does not need to be sorted.

Optional parameter 'wrap_value' is used when the domain is closed, to
indicate that both the input and output domains wrap.  For example, a
table of degree values would provide a 'wrap_value' of 360.0.

After sorting, a wrapped domain's output values must all be monotonic
in either the positive or negative direction.

For tables that don't wrap, attempts to interpolate values outside the
input range cause a ValueError exception.
"""
if wrap_value is None:
points.sort()   # Sort in-place on first element of each tuple
else:   # Force values to positive modular range
points = sorted([(p[0]%wrap_value, p[1]%wrap_value) for p in points])
# Wrapped domains must be monotonic, positive or negative
monotonic = [points[x][1] < points[x+1][1] for x in xrange(0,len(points)-1)]
num_pos_steps = monotonic.count(True)
num_neg_steps = monotonic.count(False)
if num_pos_steps > 1 and num_neg_steps > 1: # Allow 1 wrap point
raise ValueError("Table for wrapped domains must be monotonic.")
self.wrap_value = wrap_value
# Pre-compute inter-value slopes
self.x_list, self.y_list = zip(*points)
if wrap_value is None:
intervals = zip(self.x_list, self.x_list[1:], self.y_list, self.y_list[1:])
self.slopes = [(y2 - y1)/(x2 - x1) for x1, x2, y1, y2 in intervals]
else:   # Create modular slopes, including wrap element
x_rot = list(self.x_list[1:]); x_rot.append(self.x_list[0])
y_rot = list(self.y_list[1:]); y_rot.append(self.y_list[0])
intervals = zip(self.x_list, x_rot, self.y_list, y_rot)
self.slopes = [self._mod_delta(y2, y1)/self._mod_delta(x2, x1) for x1, x2, y1, y2 in intervals]

def __getitem__(self, x):       # Works with indexing operator []
result = None
if self.wrap_value is None:
if x < self.x_list[0] or x > self.x_list[-1]:
raise ValueError('Input value out-of-range: %s'%str(x))
i = bisect.bisect_left(self.x_list, x) - 1
result = self.y_list[i] + self.slopes[i] * (x - self.x_list[i])
else:
x %= self.wrap_value
i = bisect.bisect_left(self.x_list, x) - 1
result = self.y_list[i] + self.slopes[i] * self._mod_delta(x, self.x_list[i])
result %= self.wrap_value
return result
``````

And a test:

``````import nose

def xfrange(start, stop, step=1.):
""" Floating point equivalent to xrange()."""
while start < stop:
yield start
start += step

# Test simple inverted mapping for non-wrapped domain
pts = [(x,-x) for x in xfrange(1.,16., 1.)]
a = InterpolatedArray(pts)
for i in xfrange(1., 15., 0.1):
nose.tools.assert_almost_equal(a[i], -i)
# Cause expected over/under range errors
result = False  # Assume failure
try: x = a[0.5]
except ValueError: result = True
assert result
result = False
try: x = a[15.5]
except ValueError: result = True
assert result

# Test simple wrapped domain
wrap = 360.
offset = 1.234
pts = [(x,((wrap/2.) - x)) for x in xfrange(offset, wrap+offset, 10.)]
a = InterpolatedArray(pts, wrap)
for i in xfrange(0.5, wrap, 0.1):
nose.tools.assert_almost_equal(a[i], (((wrap/2.) - i)%wrap))
``````
-

But you can use linear interpolation. If your sample A value is e.g. 7.75, that resembles 2.5 degrees. If the sample B value is 180.35, it also resembles 2.5 degrees. The tricky part is when the values overflow, if that is possible at all. Just set up a bunch of unittests to check if your algorithm works and you should quickly be going.

-
All values are in the range [0,360), which includes 0 but not 360, meaning the value 360 itself is never seen, but 359.99999999 could be. For a slightly different problem, I had to simulate an intensity sensor we wanted to add to each system, so I had a wide range of values over a 0-360 range, but I didn't quite have full coverage on the "back side" at +/-180 degrees. The interpolator for that problem created a table of slopes from the data and used `bisect.bisect_left()` to do the interpolation. –  BobC Apr 9 '13 at 15:21

Answer to part 1: translation table containing the calibration values + drift value.

Basically, if DialA reports 5.7 when it is physically at 0, 9.7 when it is at 5, then I would set the drift value to be +/- .25 of the distance between each readout position to account for mechanical and readout drift.

Answer to part 2: keeping the same values on both dials, while displaying the expected position.

If you are not direction dependent, then just spin the output dial until it is in the correct position as per your calibration table.

If you are direction dependent, then you will need to track the last 1-2 values to determine direction. Once you have determined direction, you can then move the dependent dial in the direction you require, until the destination position is reached.

Your calibration table should include direction as well(positive or negative, for instance).

With the above two parts in mind, you will be able to compensate for rotational offset and directional flips, and produce an accurate position and direction reading.

Here is some code that given a calibration table, will yield position and direction, which will solve the problem of display and making the dependent dial match up with the primary dial:

``````#!/usr/bin/env python

# Calibration table
# calibrations[ device ][physical position]=recorded position
calibrations={}

calibrationsdrift=1.025

calibrations["WheelA"]={}

calibrations["WheelA"]={}
calibrations["WheelA"]["000.0"]=5.7
calibrations["WheelA"]["005.0"]=9.8
calibrations["WheelA"]["010.0"]=13.9
calibrations["WheelA"]["015.0"]=18.0

calibrations["WheelB"]={}
calibrations["WheelB"]["000.0"]=182.3
calibrations["WheelB"]["005.0"]=178.4
calibrations["WheelB"]["010.0"]=174.4
calibrations["WheelB"]["015.0"]=170.3

def physicalPosition( readout , device ):
calibration=calibrations[device]
for physicalpos,calibratedpos in calibration.items():
if readout < ( calibratedpos + calibrationsdrift ):
if readout > ( calibratedpos - calibrationsdrift ):
return physicalpos
return -0

print physicalPosition( 5.8 , "WheelA")
print physicalPosition( 9.8 , "WheelA")
print physicalPosition( 10.8 , "WheelA")

# Assumes 360 = 0, so 355 is the last position before 0
if lastposition < currentposition:
if lastposition == 000.0:
if currentposition == 355:
return -1
return 1
else:
return -1

print physicalDirection( 5.8, 10.8, "WheelA")
print physicalDirection( 10.8, 2.8, "WheelA")

print physicalDirection( 182, 174, "WheelB")
print physicalDirection( 170, 180, "WheelB")
``````

Running the program shows that the direction is determined correctly, even for WheelB, which is mounted backwards on the panel/device/etc:

``````\$ ./dials
000.0
005.0
005.0
1
-1
1
-1
``````

Note that some of the "readout" values fed to the functions are off. That is compensated for, by the drift value. Whether you need one depends on the equipment you are interfacing with.

-
My reference data is taken every 5 degrees, with SystemA used as the reference (just a convenient selection). While the physical sensor (a paper degree gauge taped to the common base) is perfectly linear, the sensors on both SystemA and SystemB exhibit a variable nonlinearity that ranges over +/- 4 degrees, so linear interpolation is absolutely necessary. I'm building an implementation to try this technique combined with linear interpolation, and will update my question when I get it working. –  BobC Apr 9 '13 at 15:05

The easiest solution is to make all of your table elements be increasing (or decreasing as the case may be), adding or subtracting 360 to individual elements to make it so. Double up the table back to back so that it covers the entire range of 0 to 360 even after all the additions and subtractions. This makes a simple linear interpolation possible. Then you can take a modulo 360 after the calculation to bring it back into range.

-
The key difficulty is knowing where/when to do such corrections. Is there a general algorithm that works even at the data wrap points? –  BobC Apr 10 '13 at 13:46
@BobC, just go through the table - if the value jumps from a really large value to a really small one, start adding 360 from that point forward. If it jumps from a small value to a large one, start subtracting 360 from that point. –  Mark Ransom Apr 10 '13 at 13:58